Abstract
Plasmonic metal nanostructures are of great interest due to their excellent physicochemical properties and promising applications in a wide range of technical fields. Among metal nanostructures, bimetallic nanostructures with desired morphologies, such as core–shell, uniform alloy and surface decoration, are of great interest due to their improved properties and superior synergetic effects. In this paper, Au/Pd nanoclusters were deposited on the surface of gold nanobipyramids (AuBPs) into a core–shell nanostructure (AuBP@AuxPd1−x) through a reductive co-precipitation method. The AuBP@AuxPd1−x nanostructure integrates effectively the advantages of plasmonic AuBPs and catalytic Pd ultrafine nanoclusters, as well as the stable Au/Pd alloy shell. The AuBP@AuxPd1−x nanostructure exhibits superior electrocatalytic activity and durability for oxygen reduction in alkaline media owing to the synergistic effect between the AuBP core and Au/Pd shell. Furthermore, the shell thickness of AuBP@AuxPd1−x nanostructures can be adjusted by varying the amount of precursor. Overall, the catalytic activity of bimetallic Au/Pd catalysts is likely to be governed by a complex interplay of contributions from the particle size and shape.
Highlights
The use of small molecule alcohols as alternatives to current hydrocarbon fuels has attracted considerable attention.[1,2] Because ethanol is an environmentally friendly energy conversion agent with fast kinetic reactions and low corrosiveness, it can be used in alkaline media
Plasmonic metal nanostructures are of great interest due to their excellent physicochemical properties and promising applications in a wide range of technical fields
Au/Pd nanoclusters were deposited on the surface of gold nanobipyramids (AuBPs) into a core–shell nanostructure (AuBP@AuxPd1Àx) through a reductive co-precipitation method
Summary
The use of small molecule alcohols (e.g. ethanol) as alternatives to current hydrocarbon fuels has attracted considerable attention.[1,2] Because ethanol is an environmentally friendly energy conversion agent with fast kinetic reactions and low corrosiveness, it can be used in alkaline media. The AuBP@AuxPd1Àx nanostructure exhibits superior electrocatalytic activity and durability for oxygen reduction in alkaline media owing to the synergistic effect between the AuBP core and Au/Pd shell. The AuBP@AuxPd1Àx nanostructures integrate effectively the advantages of plasmonic AuBPs and catalytic Pd ultra ne nanoclusters, as well as the stable Au/Pd alloy, exhibiting superior electrocatalytic activity and durability for oxygen reduction in alkaline media.
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